CN109033515A - A kind of micro gas turbine engine starting process modeling method - Google Patents
A kind of micro gas turbine engine starting process modeling method Download PDFInfo
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Abstract
The invention belongs to engine modeling technique fields, provide a kind of micro gas turbine engine starting process modeling method, steps are as follows: the modeling of micro gas turbine engine revolving speed;The performance parameter of micro gas turbine engine and the relationship modeling of revolving speed;Error analysis.Existing micro gas turbine engine modeling method is mostly the method using pure mechanism or machine learning, it is difficult to the starting process of micro gas turbine engine is accurately portrayed, and machine learning needs a large amount of test data.In engineering practice, the pure mechanism generallyd use at present operates complicated, inefficiency, and modeling accuracy is not high.The present invention provides a kind of micro gas turbine engine starting process modeling methods combined based on mechanism and discrimination method, compensate for the deficiencies in the prior art.Operation of the present invention is simple, and accuracy rate is high, and can realize the modeling of entire micro gas turbine engine.This method has certain expansion, extends to other fields.
Description
Technical field
The invention belongs to engine modeling technique fields, and in particular to a kind of micro gas turbine engine starting process is built
Mould method.
Background technique
Micro gas turbine engine is a complicated thermodynamic system, is made of compressor, combustion chamber and turbine.?
In the research process started to micro gas turbine engine, it is below how to establish micro gas turbine engine slow train revolving speed
Mathematical model and the numerical value calculating for carrying out starting performance, can provide ginseng for the control of micro gas turbine engine starting process
It examines.Therefore, it is very valuable for carrying out modeling to the starting process of micro gas turbine engine.
In terms of micro gas turbine engine modeling technique, the document published both at home and abroad is less, does not also there is correlation
Patent is related to content in this respect.In existing document, be mostly using the methods of support vector machines to engine startup into
Row modeling, but support vector machines needs a large amount of engine startup data, by the trained of inputoutput data
It is general to be sent out by gas turbine to the startup model of engine, however for newly developed micro gas turbine engine
The design parameter of motivation obtains the fuel oil plan of starting process, in order to guarantee gas-turbine unit energy Successful startup, passes through people
Work manually method complete micro gas turbine engine starting process.Combustion is established by the experimental data that manual start obtains
Then the startup model of gas eddy turbine advanced optimizes the fuel oil plan of engine startup by startup model again,
It has some limitations.
For micro gas turbine engine, current starting process modeling technique can not meet engineering gradually
Actual needs.Therefore, it explores a kind of effectively and suitable for the High Efficiency Modeling method of engineering practice as a urgent need to resolve
The problem of.Micro gas turbine engine starts modeling technique and also therefore has wide research and application prospect.
Summary of the invention
The present invention be it is big in order to solve gas-turbine unit starting process modeling data required amount of the existing technology,
Inefficiency, the not high problem of modeling accuracy, and a kind of micro gas turbine engine starting process modeling method proposed.
A kind of micro gas turbine engine starting process modeling method, comprising the following steps:
The first step, the modeling of micro gas turbine engine revolving speed;
Second step, the performance parameter of micro gas turbine engine and the relationship modeling of revolving speed;
Third step, error analysis.
It is now specifically described as follows:
The first step, the modeling of micro gas turbine engine revolving speed;
Step 1: analysis micro gas turbine engine starting process mechanism, by engine rotor effect modeling method,
The current value of motor and the tachometer value of micro gas turbine engine are started particular by micro gas turbine engine, are established
Gas-turbine unit surplus torque model, is calculated steady state fuel amount on this basis, thus the side for passing through linear interpolation
Method obtains the relationship between micro gas turbine engine fuel quantity and micro gas turbine engine revolving speed, quasi- with multinomial
The method of conjunction obtains the expression formula between micro gas turbine engine fuel quantity and revolving speed;
Step 2: according to the test data of the fuel quantity of micro gas turbine engine starting process and engine speed, and
The relational expression of the steady state fuel amount and micro gas turbine engine revolving speed built with step 1 compares, and obtains starting process
Fuel quantity and steady state fuel amount between difference;
Step 3: the fuel quantity difference that step 2 obtains can make micro gas turbine engine generate acceleration effect, due to combustion
Relationship between doses difference and micro gas turbine engine revolving speed is nonlinearity, utilizes the method for piece-wise linearization
Go the relationship between fitting fuel quantity difference and micro gas turbine engine revolving speed;
Step 4: fuel quantity difference and starter electric current collective effect generate micro gas turbine engine and accelerate effect
It answers, is integrated by the acceleration to micro gas turbine engine, to obtain the speed of micro gas turbine engine;
Second step, the performance parameter of micro gas turbine engine and the relationship modeling of revolving speed;
Step 5: since the relationship between the revolving speed and combustion gas performance parameter of micro gas turbine engine is very close, adopting
Micro gas turbine engine performance parameter (compressor delivery pressure, blower outlet temperature are obtained with the method for fitting of a polynomial
Outlet pressure etc. after outlet temperature and turbine after degree, combustor exit temperature, combustor exit pressure, turbine) and miniature gas
Relationship between turbogenerator revolving speed;
Step 6: since the polynomial computation gas-turbine unit performance parameter by generating can slow down the speed of model,
Numerical value may also be caused to calculate unstable phenomenon simultaneously, so multinomial is carried out discretization, generate the shape of one-dimensional interpolation table
Formula is conducive to the real-time for improving startup model.
Third step, error analysis.
Each performance parameter for the micro gas turbine engine startup model established and the error of test data exist
Within 5%, each performance parameter is referred to compressor delivery pressure, compressor delivery temperature, combustor exit pressure, turbine and goes out
Mouth pressure, turbine-exit temperature, micro gas turbine engine revolving speed.
Beneficial effects of the present invention:
Existing micro gas turbine engine modeling method is mostly the method using pure mechanism or machine learning, it is difficult to accurate
The starting process of micro gas turbine engine is portrayed, and machine learning needs a large amount of test data.In engineering practice, mesh
Before the pure mechanism that generallys use operate complicated, inefficiency, modeling accuracy is not high.The present invention provides one kind based on mechanism and
The micro gas turbine engine starting process modeling method that discrimination method combines, compensates for the deficiencies in the prior art.This hair
Bright easy to operate, accuracy rate is high, and can realize the modeling of entire micro gas turbine engine.This method has certain expansion
Property, extend to other fields.
Detailed description of the invention
Fig. 1 is micro gas turbine engine modeling procedure figure.
Fig. 2 is the relational graph of surplus torque and fuel quantity.
Fig. 3 is fuel quantity difference and surplus torque relational graph.
Fig. 4 is starting process modeling error comparison diagram, wherein (a) compressor delivery temperature error;(b) blower outlet
Pressure error;(c) combustor exit pressure error;(d) turbine outlet pressure error;(e) turbine-exit temperature error;(f) it fires
Machine speed error.
Specific embodiment
In order to which the purpose of the present invention, technology and advantage is more clearly understood, below in conjunction with attached drawing and example, to the present invention
It is further elaborated.
A kind of micro gas turbine engine starting process modeling method, comprising the following steps:
Step 1: the starting process of micro gas turbine engine is divided into 3 stages, and the first stage, engine speed is by zero
Start the revolving speed of generation power to turbine, engine is driven by starter completely to be accelerated;Second stage generates function by turbine
The revolving speed of rate is disengaged to starter;Phase III disengages revolving speed to slow train revolving speed by starter;
According to each stage of engine startup, it is modeled;
First stage, the revolving speed that engine speed generates power by zero to turbine (turn from zero speed to igniting
Speed), engine is driven by starter completely to be accelerated, and is met the engine rotor equation of motion, that is, is met formula (1).
M in formulast=Kst×Ist, wherein IstIndicate starter current value, KstFor starting motor torque constant, for inhomogeneity
The starter of type, value are different.Signified starter is electric starter herein.ω is the angle speed of micro gas turbine engine
Degree, J is the rotary inertia in reduction to micro gas turbine engine axis, i.e. equivalent moment of inertia, for different miniature combustions
The structure of gas eddy turbine carries out reduction using conservation of mechanical energy.Specific Reducing Caculus is referring to (2)
In formula, J1For the rotary inertia for the load 1 that micro gas turbine engine axis drives, ω1For micro gas turbine hair
The angular speed for the load 1 that motivation axis drives;J2For the rotary inertia for the load 2 that micro gas turbine engine axis drives, ω2For
The angular speed for the load 2 that micro gas turbine engine axis drives;JnLoad n's for what micro gas turbine engine axis drove
Rotary inertia, ωnFor the angular speed for the load n that micro gas turbine engine axis drives.
Second stage, engine speed disengage revolving speed by fire speed to starter, and engine is in starter and turbine
Accelerated under common drive, meets the engine rotor equation of motion, that is, meet formula (3).
In formula, MgasIt is exactly the surplus torque (M of micro gas turbine engine after lighting a firegas=MT-MC-Mf), MTRepresent whirlpool
Take turns the torque generated, MCRepresent compressor consumption torque, generally to square directly proportional, the M of rotating speed of gas compressorfIndicate that friction is drawn
The torque consumption risen, it is generally square directly proportional to revolving speed;MstIt is the torque that electric starter provides, it is identical with (1) formula.J with
Formula (1) calculating process is identical, and ω formula (1) is identical.
Phase III, engine disengage revolving speed in starter by engine under the action of remaining revolving speed and accelerate slow train revolving speed
Process, meet formula (4).
In formula, J is identical as formula (1), and ω formula (1) is identical.MgasIt is identical as formula (3) calculating process.
Step 2: the modeling of first stage micro gas turbine engine revolving speed
Firstly, engine equivalent moment of inertia are obtained by calculation (referring specifically to formula (2));Utilize equation of rotor motion
Formula, in conjunction with starter current value, according to Mst=Kst×IstStarter is calculated to be added on micro gas turbine engine axis
Torque value integrates it using single order Runge-Kutta methods (Euler's method), obtains the micro gas turbine hair of the model
Motivation revolving speed guarantees the combustion engine speed error in the revolving speed and test data of the micro gas turbine engine within 5%;
Step 3: the modeling of second stage micro gas turbine engine revolving speed
Step 3.1: engine equivalent moment of inertia are obtained by calculation (referring specifically to formula (2));Utilize rotor motion
Equation obtains combustion engine surplus torque value in conjunction with starter current value, and the torque-that combustion engine surplus torque=turbine generates is calmed the anger
Torque caused by torque-friction of machine consumption, filters out all the points that combustion engine surplus torque absolute value is zero, according to what is filtered out
The point that combustion engine surplus torque absolute value is zero confirms the corresponding fuel quantity of each point, the fuel quantity using linear interpolation method
As " the steady state fuel amount " of corresponding points;
Step 3.2: on the basis of step 3.1, carrying out fitting of a polynomial, obtain between combustion engine revolving speed and steady state fuel amount
Relational expression, relational expression is three multinomials, specific multinomial coefficient due to the difference of fuel type
Difference, the fuel used herein is natural gas, and expression is referring to formula (5):
Step 3.3: the functional relation between the surplus torque and fuel quantity difference of micro gas turbine engine is very multiple
It is miscellaneous, the non-linear of height is presented, it is simplified, which is portrayed using piecewise linear function, it is assumed that combustion engine is remaining
It is segmentation linear function relationship between torque and fuel quantity difference, i.e., is portrayed using formula (6).
Mgas=k (n) × (Wf-Wfss)+b(n) (6)
In formula, k (n), b (n) are coefficient, and different combustion engine revolving speeds, value is not identical, i.e. k (n), b (n) numerical value are combustion engine
The function of revolving speed n, (Wf—Wfss) it is difference between steady state fuel amount that Dynamic fuel amount and multinomial obtain, combustion engine revolving speed
Difference, value are also different;
Step 3.4: the surplus torque and starter of micro gas turbine engine act on the summation of the torque on combustion engine axis,
It recycles single order Runge-Kutta methods (Euler's method) to integrate it, obtains the calculated micro gas turbine of the model
Engine speed guarantees the combustion engine speed error in the revolving speed and test data of the micro gas turbine engine within 5%;
Step 3.5: in order to guarantee to mention in step 3.4 " in the revolving speed and test data of micro gas turbine engine
Combustion engine speed error within 5% ", need to be adjusted in formula (6) in real time according to the revolving speed of micro gas turbine engine
K (n), b (n), make building micro gas turbine engine startup model revolving speed farthest close to test speed.
Step 4: the modeling of phase III micro gas turbine engine revolving speed
Firstly, engine equivalent moment of inertia are obtained by calculation (referring specifically to formula (2));Utilize equation of rotor motion
The torque value that starter is added on micro gas turbine engine axis is calculated according to formula (6) in conjunction with fuel quantity in formula, benefit
It is integrated with single order Runge-Kutta methods (Euler's method), obtains the micro gas turbine engine revolving speed of the model,
Guarantee the combustion engine speed error in the revolving speed and test data of the micro gas turbine engine within 5%;It needs according to micro-
The revolving speed of type gas-turbine unit to adjust k (n), the b (n) in formula (6) in real time, starts the micro gas turbine of building
The revolving speed of machine startup model is farthest close to test speed.
Step 5: the relationship between the performance parameter and gas-turbine unit revolving speed of micro gas turbine engine is very
Closely, referring herein to the performance parameter of gas-turbine unit specifically include that compressor delivery temperature, blower outlet pressure
Five power, combustor exit pressure, turbine-exit temperature, turbine outlet pressure parameters are fitted using the data that MATLAB is carried
Tool fits the performance parameter of gas-turbine unit and the function expression of gas-turbine unit revolving speed, it may be assumed that
In formula (7), T2For compressor delivery temperature, KTFor the temperature coefficient of blower outlet, different starting operation mistakes
Journey, parameter is different, NgIndicate the revolving speed of micro gas turbine engine;
In formula (8), P2Compressor delivery pressure, KPFor the pressure coefficient of blower outlet, different starting operation processes,
Its parameter is different, NgIndicate the revolving speed of micro gas turbine engine;
In formula (9), P3CFor combustor exit pressure, KcFor the pressure coefficient of combustion chamber, different starting operation processes,
Parameter is different, NgIndicate the revolving speed of micro gas turbine engine;
P4=constant+kwp×Ng (10)
In formula (10), therefore turbine outlet pressure P4It is modeled as constant value+kwp×Ng, constant value is the 1.03 of standard atmospheric pressure
Times, kwp×NgIt is related with micro turbine engine working speed, kwpChange with the variation of micro turbine engine revolving speed;
In formula (11), T4For turbine-exit temperature, KtFor the temperature coefficient of turbine outlet, different starting operation processes,
Parameter is different, NgIndicate the revolving speed of micro gas turbine engine, NgtIndicate the rated speed of micro gas turbine engine,
NidleIndicate the slow train revolving speed of micro gas turbine engine;
Step 6: the polynomial function relationship between resulting gas-turbine unit performance parameter and revolving speed is subjected to line
Propertyization is discrete, i.e., linear discrete is carried out to formula (7), (8), (9), (10), (11), in order to guarantee discrete precision, miniature gas
The step value of turbogenerator revolving speed is taken as 0.2% × Ngt, the data after sliding-model control are put into corresponding one-dimensional linear and are inserted
It is worth table.
Error analysis: according to the test data of gas-turbine unit, compressor delivery pressure, blower outlet temperature are obtained
The parameters such as degree, combustor exit pressure, turbine outlet pressure, turbine-exit temperature, micro gas turbine engine revolving speed and combustion
Gap between machine startup model illustrates micro gas turbine engine starting process proposed by the invention within 5%
Modeling method be effective, feasible.
Claims (1)
1. a kind of micro gas turbine engine starting process modeling method, which is characterized in that steps are as follows:
Step 1: the starting process of micro gas turbine engine is divided into 3 stages, and the first stage, engine speed is by zero to whirlpool
Wheel starts to generate the revolving speed of power, and engine is driven by starter completely to be accelerated;Second stage generates power by turbine
Revolving speed is disengaged to starter;Phase III disengages revolving speed to slow train revolving speed by starter;
According to each stage of engine startup, it is modeled;
First stage, the revolving speed that engine speed generates power by zero to turbine is to start from zero speed to fire speed
Machine is driven by starter completely to be accelerated, and is met the engine rotor equation of motion, that is, is met formula (1):
M in formulast=Kst×Ist, wherein IstIndicate starter current value, KstFor starting motor torque constant;ω is miniature gas whirlpool
The angular speed of turbine, J are the rotary inertia in reduction to micro gas turbine engine axis, i.e. equivalent moment of inertia, needle
To the structure of different micro gas turbine engines, reduction is carried out using conservation of mechanical energy;Specific Reducing Caculus (2)
In formula, J1For the rotary inertia for the load 1 that micro gas turbine engine axis drives, ω1For micro gas turbine engine
The angular speed for the load 1 that axis drives;J2For the rotary inertia for the load 2 that micro gas turbine engine axis drives, ω2It is miniature
The angular speed for the load 2 that gas-turbine unit axis drives;JnFor the rotation for the load n that micro gas turbine engine axis drives
Inertia, ωnFor the angular speed for the load n that micro gas turbine engine axis drives;
Second stage, engine speed disengage revolving speed by fire speed to starter, and engine is common starter and turbine
Accelerated under drive, meet the engine rotor equation of motion, that is, meets formula (3):
In formula, MgasIt is the surplus torque M of micro gas turbine engine after lighting a firegas, MTRepresent the torque of turbine generation;MCGeneration
The torque of gauge pressure mechanism of qi consumption, it is square directly proportional to rotating speed of gas compressor;MfTorque consumption caused by rubbing is indicated, with revolving speed
It is square directly proportional;MstIt is the torque that electric starter provides, it is identical as formula (1);J is identical as formula (1), ω and formula (1) phase
Together;
Phase III, micro gas turbine engine disengage revolving speed in starter by engine and add under the action of remaining revolving speed
The process of fast slow train revolving speed meets formula (4):
In formula, J is identical as formula (1), and ω is identical as formula (1);MgasIt is identical as formula (3);
Step 2: the modeling of first stage micro gas turbine engine revolving speed
Firstly, engine equivalent moment of inertia is obtained by calculation, formula (2) are seen;Using equation of rotor motion formula, in conjunction with starting
Electromechanical flow valuve, according to Mst=Kst×IstThe torque value that starter is added on micro gas turbine engine axis is calculated, utilizes
Single order Runge-Kutta methods integrate it, obtain the micro gas turbine engine revolving speed of the model, guarantee the miniature combustion
Combustion engine speed error in the revolving speed and test data of gas eddy turbine is within 5%;
Step 3: the modeling of second stage micro gas turbine engine revolving speed
Step 3.1: engine equivalent moment of inertia is obtained by calculation, sees formula (2);Using equation of rotor motion formula, in conjunction with
Starter current value, obtains combustion engine surplus torque value, and the torque that combustion engine surplus torque=turbine generates-compressor consumption turns
Torque caused by square-friction filters out all the points that combustion engine surplus torque absolute value is zero, is turned round according to the combustion engine residue filtered out
The point that square absolute value is zero confirms that the corresponding fuel quantity of each point, the fuel quantity are corresponding points using linear interpolation method
" steady state fuel amount ";
Step 3.2: on the basis of step 3.1, carrying out fitting of a polynomial, obtain the pass between combustion engine revolving speed and steady state fuel amount
It is expression formula, relational expression is three multinomials, expression formula (5):
Step 3.3: the functional relation between the surplus torque and fuel quantity difference of micro gas turbine engine is sufficiently complex, is in
Now height is non-linear, simplifies to it, therefore, portrays the complex relationship using piecewise linear function, it is assumed that combustion engine is remaining
It is segmentation linear function relationship between torque and fuel quantity difference, i.e., is simplified using formula (6)
Mgas=k (n) × (Wf-Wfss)+b(n) (6)
In formula, k (n), b (n) are coefficient, and different combustion engine revolving speeds, value is not identical, i.e. k (n), b (n) numerical value are combustion engine revolving speed n
Function, (Wf-Wfss) it is difference between steady state fuel amount that Dynamic fuel amount and multinomial obtain, combustion engine revolving speed is different,
Value is also different;
Step 3.4: the surplus torque and starter of micro gas turbine engine act on the summation of the torque on combustion engine axis, then benefit
It is integrated with single order Runge-Kutta methods, obtains the calculated micro gas turbine engine revolving speed of the model, is guaranteed
Combustion engine speed error in the revolving speed and test data of the micro gas turbine engine is within 5%;
Step 3.5: in order to guarantee " the combustion in the revolving speed and test data of micro gas turbine engine mentioned in step 3.4
Machine speed error is within 5% ", need to be adjusted in real time according to the revolving speed of micro gas turbine engine k (n) in formula (6),
B (n) makes the revolving speed of the micro gas turbine engine startup model of building farthest close to actual test speed;
Step 4: the modeling of phase III micro gas turbine engine revolving speed
Firstly, engine equivalent moment of inertia is obtained by calculation, formula (2) are seen;Using equation of rotor motion formula, in conjunction with fuel
Amount, is calculated the torque value that starter is added on micro gas turbine engine axis according to formula (6), utilizes single order Long Ge-
Library tower method integrates it, obtains the micro gas turbine engine revolving speed of the model, guarantees that the micro gas turbine is sent out
Combustion engine speed error in the revolving speed and test data of motivation is within 5%;It need to be according to the revolving speed of micro gas turbine engine
To adjust k (n), the b (n) in formula (6) in real time, makes the revolving speed maximum journey of the micro gas turbine engine startup model of building
Ground is spent close to actual test speed;
Step 5: the relationship between the performance parameter and gas-turbine unit revolving speed of micro gas turbine engine is very close,
The performance parameter of gas-turbine unit includes compressor delivery temperature, compressor delivery pressure, combustor exit pressure, turbine
Five parameters of outlet temperature and turbine outlet pressure, the performance parameter and gas-turbine unit for being fitted gas-turbine unit turn
The function expression of speed, it may be assumed that
In formula (7), T2For compressor delivery temperature, KTFor the temperature coefficient of blower outlet, different starting operation processes,
Parameter is different, NgIndicate the revolving speed of micro gas turbine engine;
In formula (8), P2Compressor delivery pressure, KPFor the pressure coefficient of blower outlet, different starting operation processes, ginseng
Number is different, NgIndicate the revolving speed of micro gas turbine engine;
In formula (9), P3CFor combustor exit pressure, KcFor the pressure coefficient of combustion chamber, different starting operation processes, parameter
Difference, NgIndicate the revolving speed of micro gas turbine engine;
P4=constant+kwp×Ng (10)
In formula (10), therefore turbine outlet pressure P4It is modeled as constant value+kwp×Ng, constant value is 1.03 times of standard atmospheric pressure, kwp
×NgIt is related with micro turbine engine working speed, kwpChange with the variation of micro turbine engine revolving speed;
In formula (11), T4For turbine-exit temperature, KtFor the temperature coefficient of turbine outlet, different starting operation processes, parameter
Difference, NgIndicate the revolving speed of micro gas turbine engine, NgtIndicate the rated speed of micro gas turbine engine, NidleTable
Show the slow train revolving speed of micro gas turbine engine;
Step 6: the polynomial function relationship between resulting gas-turbine unit performance parameter and revolving speed is linearized
It is discrete, i.e., linear discrete is carried out to formula (7), (8), (9), (10), (11), in order to guarantee discrete precision, micro gas turbine
The step value of engine speed is taken as 0.2% × Ngt, the data after sliding-model control are put into corresponding one-line interpolation table.
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